Minimum marker densities for accurate genomic predictions and heritability estimates in three major North American and European spruce species. Soro, A., Lenz, P., Beaulieu, J., Laverdière, J., Nadeau, S., Gagnon, F., Ogut, F., Wu, H. X., Perron, M., & Bousquet, J. Heredity, Nature Publishing Group, May, 2026.
Minimum marker densities for accurate genomic predictions and heritability estimates in three major North American and European spruce species [link]Paper  doi  abstract   bibtex   
Genomic selection (GS) is being increasingly used in tree breeding with the aim to accelerate genetic gains by shortening the long breeding cycles. However, high genotyping costs remain a challenge. This study aimed to determine the optimal marker density in genome coverage to maximize GS accuracy and precision of heritability estimates for growth and wood quality traits. Thousands of SNPs representative of the exome of three major spruce species were used: 18,275 SNPs for black spruce (representing 10,894 distinct gene loci), 11,328 SNPs for white spruce (8647 gene loci), and 116,765 SNPs for Norway spruce (20,695 gene loci). For each species, a similar experimental design was used with related full-sib families replicated on two sites, and GBLUP prediction models were developed. The effect of varying the number of SNPs was examined by resampling subsets from 500 to 100,000 SNPs. Results indicated that plateaus in heritability estimates were reached as the marker density increased, stabilizing between 4000 and 8000 SNPs for a spruce genome size of around 2000 centimorgans, a trend consistent across all traits and species. Predictive ability and prediction accuracy both increased with the number of SNPs up to a similar level, beyond which further improvements were marginal. Such minimum marker densities should be financially affordable for most spruce breeding programs, striking a balance between the need for maximizing GS accuracy and that for minimizing genotyping costs. These findings should support the further deployment of GS in conifer breeding programs, with high selection precision and by reducing the financial burden of very high-density SNP coverage, even for conifers characterized by large giga-genomes.
@article{soro_minimum_2026,
	title = {Minimum marker densities for accurate genomic predictions and heritability estimates in three major {North} {American} and {European} spruce species},
	copyright = {2026 His Majesty the King in Right of Canada, as represented by the Minister of Natural Resources and the Authors},
	issn = {1365-2540},
	url = {https://www.nature.com/articles/s41437-026-00836-7},
	doi = {10.1038/s41437-026-00836-7},
	abstract = {Genomic selection (GS) is being increasingly used in tree breeding with the aim to accelerate genetic gains by shortening the long breeding cycles. However, high genotyping costs remain a challenge. This study aimed to determine the optimal marker density in genome coverage to maximize GS accuracy and precision of heritability estimates for growth and wood quality traits. Thousands of SNPs representative of the exome of three major spruce species were used: 18,275 SNPs for black spruce (representing 10,894 distinct gene loci), 11,328 SNPs for white spruce (8647 gene loci), and 116,765 SNPs for Norway spruce (20,695 gene loci). For each species, a similar experimental design was used with related full-sib families replicated on two sites, and GBLUP prediction models were developed. The effect of varying the number of SNPs was examined by resampling subsets from 500 to 100,000 SNPs. Results indicated that plateaus in heritability estimates were reached as the marker density increased, stabilizing between 4000 and 8000 SNPs for a spruce genome size of around 2000 centimorgans, a trend consistent across all traits and species. Predictive ability and prediction accuracy both increased with the number of SNPs up to a similar level, beyond which further improvements were marginal. Such minimum marker densities should be financially affordable for most spruce breeding programs, striking a balance between the need for maximizing GS accuracy and that for minimizing genotyping costs. These findings should support the further deployment of GS in conifer breeding programs, with high selection precision and by reducing the financial burden of very high-density SNP coverage, even for conifers characterized by large giga-genomes.},
	language = {en},
	urldate = {2026-05-15},
	journal = {Heredity},
	publisher = {Nature Publishing Group},
	author = {Soro, André and Lenz, Patrick and Beaulieu, Jean and Laverdière, Jean-Philippe and Nadeau, Simon and Gagnon, France and Ogut, Funda and Wu, Harry X. and Perron, Martin and Bousquet, Jean},
	month = may,
	year = {2026},
	keywords = {Comparative genomics, Ecological genetics, Forestry},
	pages = {1--16},
}
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